CN211854105U - Electromagnetic stove capable of quickly dissipating heat - Google Patents

Abstract

The application discloses quick radiating electromagnetism kitchen range, set up in electromagnetic heating mechanism below through the wind gap, cold wind can follow air intake department and get into directly to electromagnetic heating mechanism and carry out the wind heat dissipation, heat dissipation channel sets up can be with the produced heat direct direction of electromagnetic heating mechanism to the radiating groove all around the air intake, heat dissipation mechanism is in heat dissipation department with the heat discharge to the outside in the radiating groove, thereby form the one-way heat dissipation channel that has the guide function, make cold wind channel and heat dissipation channel form independent and divided operation space, can effectively improve the radiating rate, overcome the cold and hot wind channel and mix the problem that leads to electromagnetic heating mechanism life to reduce easily.

Description

Electromagnetic stove capable of quickly dissipating heat

Technical Field

The utility model relates to a technical field in the aspect of the electromagnetism stove heat dissipation especially relates to a quick radiating electromagnetism stove.

Background

Along with the idea of energy-concerving and environment-protective constantly deepens masses of users' heart, in the commercial food and beverage trade of more and more extensive application of commercial electromagnetism stove, because the repast supply volume of commercial food and beverage trade is big, consequently also high to the requirement of electromagnetism kitchen range, when a plurality of furnace ends of an electromagnetism kitchen range heat simultaneously and cook, can produce very big heat, require to dispel the heat and expel heat higher. The existing induction cooker adopts the same air inlet and outlet to ventilate and radiate heat, and the cold air channel and the radiating channel are arranged into the same channel, so that cold air and hot air are mixed together, the radiating efficiency is reduced, the heating rate of the induction cooker is low, and the electromagnetic heating component is easy to damage.

SUMMERY OF THE UTILITY MODEL

Objects of the invention

The utility model aims at providing a quick radiating electromagnetism kitchen range effectively overcomes current electromagnetism kitchen range cold wind passageway and heat dissipation channel and sets up to same passageway, leads to cold and hot wind to mix together, and reduces the radiating efficiency, leads to the not high problem of rate of heating of electromagnetism stove.

(II) technical scheme

In order to achieve the above object, the present invention adopts the following technical solution to provide a fast heat dissipation electromagnetic oven, including:

the device comprises a base with a cavity and a panel covering the upper end of the base;

the cavity is equipped with air intake, thermovent and radiating groove, the air intake is located the bottom of cavity and air intake department installs electromagnetic heating mechanism, the thermovent is located one side of cavity just one side department installs heat dissipation mechanism, one side in the cavity is equipped with the radiating groove, the radiating groove is close to the thermovent sets up, the radiating groove intercommunication the cavity with the thermovent forms the heat dissipation circulation of heat transfer.

The utility model discloses an install electromagnetic heating mechanism in the cavity, set up electromagnetic heating mechanism above the air intake, cold wind can get into electromagnetic heating mechanism from the air intake, directly carry out the air-cooled heat dissipation to electromagnetic heating mechanism, because the cavity communicates the radiating groove and forms the heat dissipation water conservancy diversion passageway, the heat dissipation water conservancy diversion passageway supplies the circulation of wind and does not mix cold wind, thereby can be directly from the cavity water conservancy diversion to the radiating groove in the heat that the electromagnetic heating mechanism produced, form concentrated heat dissipation space through the radiating groove and can carry out quick heat dissipation, moreover, heat dissipation mechanism can directly discharge the heat in the radiating groove to the outside at the radiating hole department, thereby form the quick heat dissipation channel of electromagnetism stove work, make cold wind passageway and radiating channel form independent and separated operation space, can effectively improve the radiating rate, overcome the problem that the cold and hot wind passageway mixes and easily lead to electromagnetic heating mechanism life to reduce, the cooling device has the advantages of effectively reducing cost, being simple in structure, fast in heat dissipation, safe and environment-friendly, and avoiding power utilization accidents caused by poor heat dissipation.

Further, the radiating groove is vertically arranged between the cavity and the radiating port, wherein the top of the radiating groove is communicated with the cavity, and the bottom of the radiating groove is communicated with the radiating port. Therefore, heat energy is gathered to the heat dissipation grooves through the top of the heat dissipation grooves in the cavity, and the heat dissipation grooves are discharged to the outside through the bottom of the heat dissipation grooves, so that heat dissipation spaces with distance drops can be formed between the cavity and the heat dissipation ports, transverse heat dissipation areas are saved, heat backflow is avoided, heat dissipation speed is reduced, the time for heat to be discharged outwards can be shortened, and the heat dissipation speed is improved.

Further, the heat dissipation groove is transversely arranged between the cavity and the heat dissipation port so as to be communicated between the cavity and the heat dissipation port on the same plane. From this, the radiating groove can be with the heat in the cavity direct drainage to thermovent on same horizontal plane, through horizontal direct current mode, reduces thermal three-dimensional trend, can be quicker, more directly with the heat emission to the outside in the radiating groove, improve the radiating efficiency.

Further, the radiating groove is arranged in the cavity, and is concavely arranged on one side of the cavity and integrally formed with the cavity. Therefore, the heat dissipation groove is integrally formed in the cavity, the heat dissipation outlet of the cavity and the heat dissipation inlet of the heat dissipation groove form a directly communicated heat dissipation connection mode, and the heat dissipation device is simple in structure, high in heat dissipation speed and low in processing cost.

Further, the cavity is communicated with the heat dissipation groove to form an L-shaped heat dissipation cavity. The utility model discloses connect the radiating groove in one side of cavity and form L type heat radiation structure, the radiating groove is connected in one side below of cavity wherein, cavity and radiating groove all can set up to sharp linear shape cubical space, make to form the heat dissipation space that has apart from the drop between radiating groove and the cavity, avoid the heat to flow backwards and reduce the radiating rate in to the cavity, the heat dissipation mouth is direct to be discharged the heat in the radiating groove, and the radiating rate is fast, the processing cost is low.

Further, the cavity is communicated with the heat dissipation groove to form a T-shaped heat dissipation cavity. Wherein, can connect the middle part of radiating groove in one side of cavity, the heat direct current in the cavity is to the radiating groove, and the radiating groove provides vertical heat dissipation space, and the thermovent can set up in the middle part of radiating groove so that heat dissipation mechanism directly discharges the heat to the outside, and it is fast, the processing cost is low to reduce the radiating rate radiating speed.

Furthermore, the heat dissipation opening is formed in the side face of the base, and the heat dissipation groove is formed in the back face of the inner side of the base and close to the position of the heat dissipation opening. In order to accelerate the outward heat dissipation speed of the heat dissipation groove, the heat dissipation opening is formed in the back face of the base, cold air mixing between the bottom face of the heat dissipation opening and the air inlet can be avoided, therefore, quick air exhaust heat dissipation is conducted, and the heat dissipation speed is high.

Furthermore, a sealing part is convexly formed on the peripheral edge of the cavity, a sealing groove is concavely formed in the inner surface of the panel, and the sealing part can be inserted into the sealing groove. Therefore, the cavity forms a relatively closed heat dissipation space through the concave-convex connection of the base and the panel, the heat dissipation condition which is not easily influenced by external factors is achieved, and a clear guide channel is formed, so that the heat dissipation efficiency is improved.

Further, the panel is connected top surface one side of base, the top surface distribution of panel has a plurality of heating faces, the panel can cover with rotating and close the cavity makes the heating face sets up electromagnetic heating mechanism top. Therefore, the movable panel and the cover structure of the cavity body enable the electromagnetic heating mechanism to directly heat the heating object placed on the heating surface above the air inlet, so that the cavity body forms a relatively closed heat dissipation space, therefore, under the driving force of the heat dissipation mechanism, heat flows into the heat dissipation groove in the cavity body, the heat is discharged from the heat dissipation groove, the electromagnetic heating speed is increased, the heating speed of food is increased, and the cooking time is shortened.

Furthermore, the bottom surface of the cavity is provided with a wire passing hole communicated with the outside, and the wire passing hole is formed around the air inlet. Therefore, the wire passing hole is an electric wire passing hole of the electromagnetic heating mechanism, firstly, the wire passing hole can lead the electric wire to the bottom of the base directly, and the problems of electric wire disorder and overlong electric wire when the electric wire enters from the side surface or the top surface of the base are solved; and secondly, the wire passing hole is formed in the bottom surface of the cavity and can be used for allowing a small amount of cold air to enter, so that convection is formed between the wire passing hole and the heat dissipation port indirectly, and the heat dissipation speed in the cavity is increased.

Drawings

Fig. 1 is a schematic perspective view of an electromagnetic oven with rapid heat dissipation according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a base according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a panel according to an embodiment of the present invention.

Reference numerals:

the electromagnetic heating device comprises a base 1, a cavity 11, an air inlet 12, a heat dissipation port 13, a heat dissipation groove 14, a wire passing hole 15, a sealing portion 16, a panel 2, a heating surface 21, a sealing groove 22, an electromagnetic heating mechanism 3, a heat dissipation mechanism 4 and a control panel 5.

Detailed Description

The technical solution and the advantages of the present invention will be more clear and clear by further describing the embodiments of the present invention with reference to the drawings of the specification. The embodiments described below are exemplary and are intended to be illustrative of the present invention, but should not be construed as limiting the invention.

As shown in fig. 1-3, the utility model discloses a quick radiating electromagnetic stove, including: a base 1 and a panel 2 covering the upper end of the base 1; the top surface of the base 1 is concave downwards to form a cavity 11, the cavity 11 is provided with air inlets 12 communicated with the outside, heat dissipation ports 13 communicated with the outside and heat dissipation grooves 14, the air inlets 12 are arranged on the bottom surface of the cavity 11 at intervals, an electromagnetic heating mechanism 3 is arranged above each air inlet 12, the heat dissipation ports 13 are positioned on one side of the cavity 11, and the heat dissipation mechanisms 4 are arranged at the heat dissipation ports 13; the electromagnetic heating mechanism 3 is installed above the air inlet 12, so that a heat dissipation channel is formed between the plurality of electromagnetic heating mechanisms 3 in the cavity 11, the heat dissipation groove 14 is connected to one side of the cavity 11, and a heat dissipation port 13 is formed in one side of the heat dissipation groove 14, so that the heat dissipation groove 14 is communicated with the heat dissipation flow guide channel formed between the cavity 11 and the heat dissipation port 13.

That is, the periphery of the electromagnetic heating mechanism 3 is provided with a heat dissipation channel, cold air can enter the electromagnetic heating mechanism 3 from the air inlet 12, the electromagnetic heating mechanism 3 is directly cooled by the cold air, the heat dissipation channel in the cavity 11 is surrounded on the periphery of the electromagnetic heating mechanism 3, the heat generated by the electromagnetic heating mechanism 3 can be directly guided to the heat dissipation groove 14, the heat in the heat dissipation groove 14 is discharged to the outside from the heat dissipation mechanism 4 at the heat dissipation port 13, so that the one-way heat dissipation channel with the guiding function is formed, the cold air channel and the heat dissipation channel form independent and separated operation space, and the heat dissipation speed can be effectively improved.

As shown in fig. 1 and 2, the heat sink 14 is vertically disposed between the cavity 11 and the heat dissipation opening 13, wherein the top of the heat sink 14 is communicated with the cavity 11, and the bottom of the heat sink 14 is communicated with the heat dissipation opening 13. Or, the heat dissipation port 13 is arranged in the middle of the heat dissipation groove 14, so long as the heat dissipation groove 14 can form a heat dissipation space with a distance drop between the heat dissipation port 13 and the cavity 11, the heat energy in the cavity 11 can be gathered to the heat dissipation groove 14, and then the heat energy is discharged to the outside from the bottom or the middle of the heat dissipation groove 14, so that the heat backflow can be effectively avoided, the heat dissipation speed is reduced, the time for heat to be discharged outwards can be shortened, and the heat dissipation speed is improved.

As shown in fig. 1 and 2, the heat sink 14 is disposed in the cavity 11, and the heat sink 14 is recessed from one side of the cavity 11 and is integrally formed with the cavity 11, wherein preferably, in some embodiments, the cavity 11 is communicated with the heat sink 14 to form an L-shaped heat dissipation cavity. The utility model discloses well cavity 11 and radiating groove 14's whole cavity shape all can set up to the linearity, and wherein each face including the cavity can set up to the plane, and each face also including the cavity can set up to the curved surface form, requires to set up according to the heating condition of difference to laminating electromagnetic heating mechanism sets up different sharp heat dissipation channel or curve heat dissipation channel and dispels the heat. In order to realize the guiding heat dissipation, the heat dissipation groove 14 can be connected to one side of the cavity 11, so that the cavity 11 and the heat dissipation groove 14 are connected to form an L-shaped heat dissipation structure, and the structure is simple, the heat dissipation speed is high, and the processing cost is low.

In order to accelerate the outward heat dissipation speed of the heat dissipation groove 14, the heat dissipation port 13 can be vertically arranged on the side surface of the heat dissipation groove 14, and the heat in the heat dissipation groove 14 can be quickly and intuitively dissipated to the outside through the vertical heat dissipation area of the heat dissipation port 13; the heat dissipation opening 13 may be provided laterally on the side of the heat dissipation portion 15. The opening shape of the heat dissipation opening 13 may be a circular net shape, a rectangular net shape, or an irregular net shape, wherein the net structure may be a regular net shape or a regular net shape.

As shown in fig. 2, in order to increase the speed of heat dissipation from the heat dissipation grooves 14, a plurality of heat dissipation openings 13 are formed in the back surface of the base 1, and the heat dissipation grooves 14 are transversely formed in the back surface of the inner side of the base 1 and near the heat dissipation openings 13. Therefore, the plurality of heat dissipation ports 13 can be transversely arranged in the side surface of the heat dissipation groove 14, so that the plurality of heat dissipation mechanisms 4 can perform quick air exhaust heat dissipation at the heat dissipation ports 13, and the heat dissipation speed is high.

As shown in fig. 1, a sealing portion 16 is formed at the periphery of the cavity 11, a sealing groove 22 is formed at the inner surface of the panel 2, and the sealing portion 16 can be inserted into the sealing groove 22 to cover the upper end of the cavity 11 with the panel 2.

Preferably, as shown in fig. 1, the panel 2 is connected to one side of the base 1, the panel 2 can rotate to cover the cavity 11 on the top surface of the base 1, a plurality of heating surfaces 21 are distributed on the top surface of the panel 2, and the heating surfaces 21 are arranged above the electromagnetic heating mechanism 3. Therefore, the movable cover structure of the panel 2 and the cavity 11 can enable the electromagnetic heating mechanism 3 to directly heat the heating object on the heating surface above the air inlet 12, so that the heat is guided to the heat dissipation groove 14 in the cavity 11 to be discharged outside under the driving force of the heat dissipation mechanism 4, the electromagnetic heating speed is increased, the heating speed of food is increased, and the cooking time is shortened.

As shown in fig. 1 and 2, the bottom surface of the cavity 11 is provided with a plurality of wire passing holes 15, the wire passing holes 15 are arranged around the air inlet 12, and the wire passing holes 15 are communicated to the outer side of the bottom surface of the base 1. Wherein, the wire through holes 15 are arranged at four corners of the cavity 11 or in the middle of the cavity 11.

In order to realize the convenience of operation, make things convenient for the inertia of staff's operation, the utility model discloses still include control panel 5, it is concrete, as shown in fig. 1, control panel 5 sets up openly in the outside of base 1, and electricity connection electromagnetic heating mechanism 3 for the heating work of control electromagnetic heating mechanism 3. In some embodiments, as shown in fig. 3, the control panel 5 may also be disposed on the panel 2 and installed in front of the heating surface 21, and the control panel 5 and the heating surface 21 may be disposed on the same plane, so as to be more suitable for the heating control operation during cooking, which is convenient, efficient, practical and simple.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (10)

1. An induction cooking range capable of dissipating heat quickly, comprising:

the device comprises a base with a cavity and a panel covering the upper end of the base;

the cavity is equipped with air intake, thermovent and radiating groove, the air intake is located the bottom of cavity and air intake department installs electromagnetic heating mechanism, the thermovent is located one side of cavity just one side department installs heat dissipation mechanism, one side in the cavity is equipped with the radiating groove, the radiating groove is close to the thermovent sets up, the radiating groove intercommunication the cavity with the thermovent forms the heat dissipation circulation of heat transfer.

2. The rapid heat dissipation induction cooking range of claim 1, wherein: the radiating groove is vertically arranged between the cavity and the radiating port, wherein the top of the radiating groove is communicated with the cavity, and the bottom of the radiating groove is communicated with the radiating port.

3. The rapid heat dissipation induction cooking range of claim 1, wherein: the heat dissipation groove is transversely arranged between the cavity and the heat dissipation port so as to be communicated between the cavity and the heat dissipation port on the same plane.

4. The rapid heat dissipation induction cooking range according to any one of claims 1 to 3, wherein: the radiating groove is arranged in the cavity, and is concavely arranged on one side of the cavity and integrally formed with the cavity.

5. The rapid heat dissipation induction cooking range according to claim 4, wherein: the cavity is communicated with the heat dissipation groove to form an L-shaped heat dissipation cavity.

6. The rapid heat dissipation induction cooking range according to claim 4, wherein: the cavity is communicated with the heat dissipation groove to form a T-shaped heat dissipation cavity.

7. The rapid heat dissipation induction cooking range according to claim 1, 2, 3, 5 or 6, wherein: the heat dissipation opening is formed in the side face of the base, and the heat dissipation groove is formed in the back face of the inner side of the base and close to the position of the heat dissipation opening.

8. The rapid heat dissipation induction cooking range of claim 7, wherein: the periphery edge epirelief of cavity forms sealing, the concave seal groove that is equipped with of inner face of panel, sealing can insert in the seal groove.

9. The rapid heat dissipation induction cooking range of claim 8, wherein: the panel is connected top surface one side of base, the top surface distribution of panel has a plurality of heating surfaces, the panel can cover with rotating and close the cavity makes the heating surface sets up electromagnetic heating mechanism top.

10. The rapid heat dissipation induction cooking range of claim 9, wherein: the bottom surface of the cavity is provided with a wire passing hole communicated with the outside, and the wire passing hole is formed around the air inlet.

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